// Licensed to the .NET Foundation under one or more agreements.
// The .NET Foundation licenses this file to you under the MIT license.

#include "common.h"

#include "disassembler.h"
#include "dllimport.h"

#if USE_DISASSEMBLER

// TODO: Which contracts should be used where? Currently, everything is using LIMITED_METHOD_CONTRACT.

#if USE_COREDISTOOLS_DISASSEMBLER
HMODULE Disassembler::s_libraryHandle = nullptr;
InitDisasm_t *Disassembler::External_InitDisasm = nullptr;
FinishDisasm_t *Disassembler::External_FinishDisasm = nullptr;
DisasmInstruction_t *Disassembler::External_DisasmInstruction = nullptr;
#endif // USE_COREDISTOOLS_DISASSEMBLER

Disassembler::ExternalDisassembler *Disassembler::s_availableExternalDisassembler = nullptr;

#if defined(TARGET_AMD64) || defined(TARGET_X86)
// static
bool Disassembler::IsRexPrefix(UINT8 potentialRexByte)
{
    LIMITED_METHOD_CONTRACT;

#ifdef TARGET_AMD64
    return (potentialRexByte & 0xf0) == REX_PREFIX_BASE;
#else // !TARGET_AMD64
    return false;
#endif // TARGET_AMD64
}

// static
UINT8 Disassembler::DecodeModFromModRm(UINT8 modRm)
{
    LIMITED_METHOD_CONTRACT;
    return modRm >> 6;
}

// static
UINT8 Disassembler::DecodeRegOrOpCodeFromModRm(UINT8 modRm)
{
    LIMITED_METHOD_CONTRACT;
    return (modRm >> 3) & 0x7;
}

// static
UINT8 Disassembler::DecodeRmFromModRm(UINT8 modRm)
{
    LIMITED_METHOD_CONTRACT;
    return modRm & 0x7;
}
#endif // defined(TARGET_AMD64) || defined(TARGET_X86)

// static
bool Disassembler::IsAvailable()
{
    LIMITED_METHOD_CONTRACT;

#if USE_COREDISTOOLS_DISASSEMBLER
    return s_libraryHandle != nullptr;
#else // !USE_COREDISTOOLS_DISASSEMBLER
    return true;
#endif // USE_COREDISTOOLS_DISASSEMBLER
}

#if _DEBUG
#define DISPLAYERROR(FMT, ...) wprintf(FMT, __VA_ARGS__)
#else
#define DISPLAYERROR(FMT, ...) (void)0
#endif

namespace
{
    HMODULE LoadCoreDisToolsModule(PathString &libPath)
    {
        LIMITED_METHOD_CONTRACT;

        LPCWSTR sysDirectory = GetInternalSystemDirectory();
        LPCWSTR libFileName = MAKEDLLNAME(W("coredistools"));

        // Look for the coredistools module next to the clr binary
        libPath.AppendPrintf(W("%s%s"), sysDirectory, libFileName);

        LPCWSTR libraryName = libPath.GetUnicode();
        return CLRLoadLibrary(libraryName);
    }
}

void Disassembler::StaticInitialize()
{
    LIMITED_METHOD_CONTRACT;

#if USE_COREDISTOOLS_DISASSEMBLER
    _ASSERTE(!IsAvailable());

    PathString libPath;
    HMODULE libraryHandle = LoadCoreDisToolsModule(libPath);
    if (libraryHandle == nullptr)
        return;

    External_InitDisasm =
        reinterpret_cast<decltype(External_InitDisasm)>(GetProcAddress(libraryHandle, "InitDisasm"));
    if (External_InitDisasm == nullptr)
    {
        DISPLAYERROR(
            W("GetProcAddress failed for library '%s', function 'InitDisasm': error %u\n"),
            libPath.GetUnicode(),
            GetLastError());
        return;
    }

    External_DisasmInstruction =
        reinterpret_cast<decltype(External_DisasmInstruction)>(GetProcAddress(libraryHandle, "DisasmInstruction"));
    if (External_DisasmInstruction == nullptr)
    {
        DISPLAYERROR(
            W("GetProcAddress failed for library '%s', function 'DisasmInstruction': error %u\n"),
            libPath.GetUnicode(),
            GetLastError());
        return;
    }

    External_FinishDisasm =
        reinterpret_cast<decltype(External_FinishDisasm)>(GetProcAddress(libraryHandle, "FinishDisasm"));
    if (External_FinishDisasm == nullptr)
    {
        DISPLAYERROR(
            W("GetProcAddress failed for library '%s', function 'FinishDisasm': error %u\n"),
            libPath.GetUnicode(),
            GetLastError());
        return;
    }

    // Set this last to indicate successful load of the library and all exports
    s_libraryHandle = libraryHandle;
    _ASSERTE(IsAvailable());
#endif // USE_COREDISTOOLS_DISASSEMBLER
}

// static
void Disassembler::StaticClose()
{
    LIMITED_METHOD_CONTRACT;

    if (!IsAvailable())
    {
        return;
    }

#if USE_COREDISTOOLS_DISASSEMBLER
    CLRFreeLibrary(s_libraryHandle);
    s_libraryHandle = nullptr;
#endif
}

Disassembler::Disassembler()
{
    LIMITED_METHOD_CONTRACT;
    _ASSERTE(IsAvailable());

    // TODO: Is it ok to save and reuse an instance of the LLVM-based disassembler? It may later be used from a different
    // thread, and it may be deleted from a different thread than the one from which it was created.

    // Try to get an external disassembler that is already available for use before creating one
    ExternalDisassembler *externalDisassembler =
        FastInterlockExchangePointer(&s_availableExternalDisassembler, static_cast<ExternalDisassembler *>(nullptr));
    if (externalDisassembler == nullptr)
    {
    #if USE_COREDISTOOLS_DISASSEMBLER
        // First parameter:
        // - Empty string for the current architecture
        // - A string of the form "x86_64-pc-win32"
        externalDisassembler = External_InitDisasm(Target_Host);
    #elif USE_MSVC_DISASSEMBLER
    #ifdef TARGET_X86
        externalDisassembler = ExternalDisassembler::PdisNew(ExternalDisassembler::distX86);
    #elif defined(TARGET_AMD64)
        externalDisassembler = ExternalDisassembler::PdisNew(ExternalDisassembler::distX8664);
    #endif // defined(TARGET_X86) || defined(TARGET_AMD64)
    #endif // USE_COREDISTOOLS_DISASSEMBLER || USE_MSVC_DISASSEMBLER
    }

    _ASSERTE(externalDisassembler != nullptr);
    m_externalDisassembler = externalDisassembler;
}

Disassembler::~Disassembler()
{
    LIMITED_METHOD_CONTRACT;
    _ASSERTE(IsAvailable());

    // Save the external disassembler for future use. We only save one instance, so delete a previously saved one.
    ExternalDisassembler *externalDisassemblerToDelete =
        FastInterlockExchangePointer(&s_availableExternalDisassembler, m_externalDisassembler);
    if (externalDisassemblerToDelete == nullptr)
    {
        return;
    }

#if USE_COREDISTOOLS_DISASSEMBLER
    External_FinishDisasm(externalDisassemblerToDelete);
#elif USE_MSVC_DISASSEMBLER
    delete externalDisassemblerToDelete;
#endif // USE_COREDISTOOLS_DISASSEMBLER || USE_MSVC_DISASSEMBLER
}

SIZE_T Disassembler::DisassembleInstruction(const UINT8 *code, SIZE_T codeLength, InstructionType *instructionTypeRef) const
{
    LIMITED_METHOD_CONTRACT;
    _ASSERTE(IsAvailable());

#if USE_COREDISTOOLS_DISASSEMBLER
    SIZE_T instructionLength = External_DisasmInstruction(m_externalDisassembler, code, code, codeLength);
#elif USE_MSVC_DISASSEMBLER
    SIZE_T instructionLength =
        m_externalDisassembler->CbDisassemble(reinterpret_cast<ExternalDisassembler::ADDR>(code), code, codeLength);
#endif // USE_COREDISTOOLS_DISASSEMBLER || USE_MSVC_DISASSEMBLER
    _ASSERTE(instructionLength <= codeLength);

    if (instructionTypeRef != nullptr)
    {
        if (instructionLength == 0)
        {
            *instructionTypeRef = InstructionType::Unknown;
        }
        else
        {
        #if USE_COREDISTOOLS_DISASSEMBLER
            *instructionTypeRef = DetermineInstructionType(code, instructionLength);
        #elif USE_MSVC_DISASSEMBLER
            *instructionTypeRef = DetermineInstructionType(m_externalDisassembler->Trmt());
        #endif // USE_COREDISTOOLS_DISASSEMBLER || USE_MSVC_DISASSEMBLER
        }
    }

    return instructionLength;
}

// static
InstructionType Disassembler::DetermineInstructionType(
#if USE_COREDISTOOLS_DISASSEMBLER
    const UINT8 *instructionCode, SIZE_T instructionCodeLength
#elif USE_MSVC_DISASSEMBLER
    ExternalDisassembler::TRMT terminationType
#endif // USE_COREDISTOOLS_DISASSEMBLER || USE_MSVC_DISASSEMBLER
    )
{
    LIMITED_METHOD_CONTRACT;

#if USE_COREDISTOOLS_DISASSEMBLER
    _ASSERTE(instructionCodeLength != 0);

    SIZE_T i = 0;
    if (Disassembler::IsRexPrefix(instructionCode[i]))
    {
        ++i;
    }

    switch (instructionCode[i])
    {
        case 0xe8: // call near rel
        #ifdef TARGET_X86
        case 0x9a: // call far ptr
        #endif // TARGET_X86
            return InstructionType::Call_DirectUnconditional;

        case 0xff:
            ++i;
            if (i >= instructionCodeLength)
            {
                break;
            }

            switch (Disassembler::DecodeRegOrOpCodeFromModRm(instructionCode[i]))
            {
                case 2: // call near r/m
                case 3: // call far m
                    return InstructionType::Call_IndirectUnconditional;

                case 4: // jmp near r/m
                case 5: // jmp far m
                    return InstructionType::Branch_IndirectUnconditional;
            }
            break;
    }
#elif USE_MSVC_DISASSEMBLER
    switch (terminationType)
    {
        case ExternalDisassembler::trmtCall:
            return InstructionType::Call_DirectUnconditional;

        case ExternalDisassembler::trmtCallInd:
            return InstructionType::Call_IndirectUnconditional;

        case ExternalDisassembler::trmtBraInd:
            return InstructionType::Branch_IndirectUnconditional;
    }
#endif // USE_COREDISTOOLS_DISASSEMBLER || USE_MSVC_DISASSEMBLER

    return InstructionType::Unknown;
}

#endif // USE_DISASSEMBLER
